Electrically operated food processor

ABSTRACT

The invention relates to an electrically operated food processor (1) for preparing a cooked product, which exhibits a basic unit (14), a vessel (2) with an agitator (18) that can be inserted into the basic unit (14), a heating device (9) allocated to the vessel (2), a temperature sensor (5), a transceiver device (12) for communicating with the temperature sensor (5), and an evaluator (13) for evaluating the measurement data received from the temperature sensor (5). In order to provide an electric food processor (1) with an alternative connection between the temperature sensor (5) and evaluator (13), it is proposed that the temperature sensor (5) be a surface acoustic wave sensor (SAW sensor).

Applicant claims priority under 35 U.S.C. § 119 of European ApplicationNo. 15189134.8 filed on Oct. 9, 2015, the disclosure of which isincorporated by reference.

TECHNICAL FIELD

The invention initially relates to an electrically operated foodprocessor, in particular to a cooker-mixer, for preparing a cookedproduct, which exhibits a basic unit, a vessel with an agitator that canbe inserted into the basic unit, a heating device allocated to thevessel, a temperature sensor, a transceiver device for communicatingwith the temperature sensor, and an evaluator for evaluating themeasurement data received from the temperature sensor.

The invention further relates to a cooking container, in particular to acooking attachment and/or cooking insert, for a heatable vessel of afood processor, wherein the cooking container exhibits one or more flooropenings, through which steam exiting the vessel can enter the cookingcontainer, and condensate from the cooking container can flow into thevessel.

In addition, the invention relates to a method for operating a foodprocessor, in particular a cooker-mixer.

PRIOR ART

Food processors of the aforementioned type are known in prior art.

For example, publication DE 20 2011 050 875 U1 discloses such anelectrical food processor with a heatable mixing vessel, whichincorporates an agitator, wherein the floor of the heating vessel can beheated with a heating device, and wherein several temperature sensorsfor acquiring the temperature of a cooked product present in the mixingvessel are arranged in the mixing vessel wall. The temperature sensorsare designed as NTC elements, which are connected with an evaluator bymeans of electrical cables.

SUMMARY OF THE INVENTION

Proceeding from the above, the object of the invention is to create anelectric food processor with an alternative connection between thetemperature sensor and evaluator.

In order to achieve the aforementioned object, the invention proposesthat the temperature sensor be a surface acoustic wave sensor (SAWsensor).

According to the invention, the temperature sensor is now a surfaceacoustic wave sensor (SAW sensor), which enables a wireless temperaturemeasurement based on surface acoustic waves. Such a wireless temperaturesensor communicates with a transceiver that is spatially separated fromthe temperature sensor, and can be part of the evaluator and/orcommunicate with the evaluator. The temperature sensor exhibits anintegrated antenna, wherein the transceiver also exhibits an antenna,and is advantageously integrated into the food processor, whichaccommodates the heatable vessel. The wireless temperature measurementfeature makes it especially easy to separate or remove the temperaturesensor from the food processor.

It is further proposed that the temperature sensor be situated in and/oron an element of the food processor that can be spatially variedrelative to the basic unit, in particular the vessel and/or a cookingcontainer that can be situated on and/or in the vessel and/or a spatulafor manipulating the cooked product. Designing the temperature sensor asa SAW sensor now makes it especially easy to situate the latter onspatially variable elements of the food processor, i.e., on elementsthat can be separated or removed from the basic unit, for example forcleaning purposes. This includes the heatable vessel itself on the onehand, and on the other any required accessories used, for example acooking container, a spatula for manipulating the cooked product or thelike.

Cooking containers, for example cooking attachments or cooking inserts,are sufficiently known in prior art. The floor area of the cookingcontainer usually exhibits partial perforations, through which steamfrom the vessel can enter the cooking container. Condensate forminginside of the cooking container can in turn flow through theperforations into the vessel. If necessary, the cooking container can besealed by a cover.

Another spatially variable element of the food processor is a spatula,for example, which can be used for introducing ingredients into thevessel. In addition, the spatula can also be used to manually stir thecooked product or the like. Within the meaning of the invention,additional locally variable elements of the food processor are alsoconceivable, which are usually designed or provided for coming intocontact with the cooked product. When the spatially variable elementcomes into contact with the cooked product, the temperature sensorsituated in or on the spatially variable element automatically alsocomes into indirect or direct (thermal) contact with the cooked product,thereby enabling a reliable temperature measurement.

It is further proposed that the electrically operated food processorexhibit at least two temperature sensors, which are situated in and/oron various elements of the food processor, in particular in cookingzones of the vessel and/or cooking container that exhibit differenttemperatures. Since the heating device of the electrically operated foodprocessor is usually allocated to the floor area of the vessel, acharacteristic temperature distribution arises inside of the vessel andpotentially the cooking container, wherein areas (cooking zones) with ahigher or lower temperature come about. According to the invention,temperature sensors are now used in the same or different cooking zonesof the vessel or cooking container. For this purpose, the temperaturesensors can be situated not just on different partial areas of the samespatially variable element of the food processor, but rather also inand/or on different spatially variable elements of the food processor,for example specifically on a wall of the vessel on the one hand, and onthe other hand on a spatula, or also on the spatula and on a cover ofthe vessel, etc. A plurality of different combinations is hereconceivable. It is recommended in particular that the temperaturesensors be used in various cooking zones. Based on the measurement datameasured by the temperature sensors, the heating device can be operatedin such a way that as homogenous a temperature distribution as possiblecomes about inside of the vessel or cooking container.

Apart from the electrically operated food processor discussed above, theinvention also proposes a cooking container, in particular a cookingattachment and/or a cooking insert, for a heatable vessel of a foodprocessor, wherein the cooking container exhibits one or more flooropenings, through which steam exiting the vessel can enter into thecooking container, and condensate can flow from the cooking containerinto the vessel, wherein the cooking container exhibits a temperaturesensor, in particular a surface acoustic wave sensor (SAW sensor). Thisconfiguration now makes it possible to measure the temperature of thecooking container and/or the cooked product contained therein. As aconsequence, the cooking process and/or cooking quality can bedetermined especially informatively, and used for the continuedtreatment of the cooked product. For example, the determined temperaturecan be used for regulating the heating device of the heatable vessel, sothat various cooked products can be optimally stored, and a recipe to beprepared succeeds optimally.

It is proposed that the temperature sensor be situated in or on a wallof the cooking container. The temperature sensor can thus be situatedeither on a surface of the cooking container, for example adhesivelybonded to the wall, or embedded into the material of the cookingcontainer, so that the temperature sensor either does not protrude overthe contour of the cooking container, or alternatively is situated as aprotruding temperature element, so that the latter extends into thecooked product, for example like a bar. For example, if the cookingcontainer is made out of a plastic, the temperature sensor can beembedded into the material of the cooking container, i.e., be completelyenveloped by the plastic. In particular plastic injection processes aresuitable in this regard. If the temperature sensor is a SAW sensor, thelatter is advantageously likewise embedded in a plastic. However, it isalternatively also possible to position the temperature sensor freely inthe cooked product, for example immerse it into the cooked product orlay it on the surface of the cooked product. A plurality of temperaturesensors can advantageously be provided inside of the cooking container,wherein the latter are advantageously uniformly distributed over thevolume of the cooked product, and overall measure both the temperatureon the cooked product surface and the temperature inside of the cookedproduct. This makes it possible to ensure a homogeneous temperaturedistribution inside of the cooked product, which not least also resultsin a successful preparation of the cooked product.

It is proposed that the cooking container exhibit a plurality of cookingzones, wherein each cooking zone has allocated to it its own temperaturesensor. For example, the cooking zones can differ in terms of theirposition inside of the cooking container. For example, a first cookingzone can be formed in a central volume region of the cooking container,while a second cooking zone lies directly against a wall of the cookingcontainer. The cooking zones can differ in terms of the cooking zonetemperature that results at a prescribed steam temperature or thearising cooking zone temperature range, wherein a cooking zone lyingclose to the floor openings in the cooking container routinely exhibitsa higher temperature than a cooking zone located further away from it.In addition, the cooking container can also exhibit a cooking containerinsert, which forms an additional shelf on which cooked product can alsobe situated. The cooking container insert here comprises a first cookingzone, for example, while the remaining region of the cooking containerforms a second cooking zone. The steam rising from a heatable vessel ofa food processor first penetrates through the cooked product situated inthe second cooking zone, and then through the cooked product situated inthe first cooking zone. In this regard, the second cooking zone usuallyexhibits a higher temperature than the first cooking zone, so that it isrecommended that only cooked products to be heated slightly be placed inthe cooking container insert. Success in preparing the cooked productssituated in the cooking container can be evaluated based on themeasurement data recorded by the temperature sensors. Depending on thelatter, additional preparation steps can be determined, for examplemixing or rearranging cooked product, increasing the temperature of aheating device allocated to the heatable vessel or the like.

Therefore, it is proposed in particular that the cooking zones exhibitvarying distances from the floor openings of the cooking container. Forexample, this can be achieved by forming them in the area of a wall ofthe cooking container or directly in the area of the floor openings. Thecooking zones can merge smoothly into each other or be separated fromeach other, for example by ribs, bars, walls or the like. In addition,different cooking zones can also be formed in the direction of the steamrising out of the heatable vessel through the cooking container inseveral stages one over the other, for example by means of a cookingcontainer insert of the kind described above inside of the cookingcontainer.

It is further proposed that the cooking container exhibit a heatingdevice that heats independently of the steam exiting the vessel. Thecooking container thus has its own heating device, so that the cookedproduct to be prepared in the cooking container is not or notexclusively heated by steam rising out of the heatable vessel of thefood processor. As a consequence, it is possible to specifically controlthe temperature of the cooking container, and hence in particular alsoof the cooked product, or especially advantageously to regulate thelatter based on the temperature measured by the temperature sensor. Inan especially advantageous way, this yields a cooking container thatexhibits both a heating device and a temperature sensor, which checksthe result of a heating process and again initiates an adjustment of theheating capacity or heating duration of the heating device as needed. Asa consequence, the cooking container can only be heated by the steam ofthe heatable vessel in one embodiment. The entire cooking container andpotentially the different cooking zones contained therein are hereheated by means of a central heating element. By contrast, a specificadjustment of the temperature inside of the cooking container, and hencealso inside of the cooked product, can also be achieved according toanother embodiment during the operation of one or more heating devicesof the cooking container. As opposed to exposure to steam, the functionof the heating device of the cooking container is also independent of aspecific orientation of the cooking container relative to the heatablevessel.

Both the heating device and temperature sensor can be situated invarying positions in or on the cooking container, so that even cookedproduct located a distance away from the heatable vessel can be heatedjust as fast as the cooked product located in proximity to the heatablevessel. Because the heating device operates independently of the steamexiting the vessel, the cooking process inside of the cooking containercan already begin when a liquid contained in the heatable vessel is notyet boiling, so that no steam gets into the cooking container either. Asa consequence, the heating device makes the cooking containerindependent of steam formation inside of the vessel. The heating devicenot least also makes it possible to use the cooking container as anactively heat retaining container. The cooking container can here alsobe used by itself, completely independently of a food processor or itsheatable vessel. This in particular in combination with the temperaturesensor according to the invention, and especially advantageously with acontrol circuit that contains the temperature sensor and heating device.

It is proposed that the heating device exhibit a plurality of partialheating devices, which in particular are situated in different cookingzones of the cooking container. The partial heating devices can here belocated at defined distances in or on the wall of the cooking container,thereby yielding a homogeneous heating of the cooked product present inthe cooking container. The partial heating devices can hereadvantageously form different cooking zones of the cooking container,for example also be provided on a cooking container insert of thecooking container. Each cooking zone here advantageously exhibits itsown temperature sensor and its own partial heating device, so that thetemperature can be controlled and/or regulated separately in eachcooking zone, and monitored by the respective temperature sensor. Justas with the temperature sensor, the heating device or partial heatingdevice can be situated in or on the wall of the cooking container. Forexample, the partial heating devices can be provided in the wall arounda circle or along a strip. The latter are advantageously embedded intothe material of the wall, thereby eliminating the possibility of contactwith the cooked product to be prepared.

Finally, the invention also proposes a method for operating a foodprocessor, in particular a cooker-mixer, for preparing a cooked product,wherein at least two temperatures, in particular temperatures of acooked product to be prepared, are measured at positions deviating fromeach other by means of at least two temperature sensors situated inand/or on elements of the food processor that are spatially variablerelative to the basic unit, and wherein at least one partial heatingdevice of a plurality of partial heating devices of a heating devicesituated in the food processor is operated as a function of thedetermined current temperatures.

Therefore, the invention proposes a method for operating the foodprocessor with a temperature regulating method as a function of at leasttwo measured temperatures. For example, when measuring a cooked producttemperature at a first position that lies below the temperature of asecond position, the heating capacity of the heating device can beraised or lowered accordingly, so that the temperature values come toapproximate each other. The heating device is here advantageouslyoperated at an elevated temperature or with a longer heating duration inrelation to a partial heating device allocated to the first position.

In a preferred embodiment, the method further provides that atransceiver device be formed on the basic unit, which transmits anelectromagnetic excitation signal, wherein the temperature sensortransmits a temperature-dependent response signal, and the transceiverdevice receives the response signal, wherein the current temperature isdetermined by comparing the response signal [with] thetemperature-dependent reference signal.

As a consequence, the measuring method preferably advantageously makesuse of temperature-dependent surface waves, which are excited in thetemperature sensor, and can be measured on the surface of thetemperature sensor. The temperature sensor is here excited to oscillateby high-frequency electromagnetic waves, wherein the temperature of thecooked product can be derived based upon the temperature dependence ofthe electromagnetic waves sent back by the temperature sensor. Thehigh-frequency electromagnetic waves are transmitted to the temperaturesensor via the transceiver device. The waves sent back by thetemperature sensor as a response signal are subsequently received by thetransceiver device, and relayed to the evaluator of the basic unit ofthe food processor. In order to derive the cooked product temperature asprecisely as possible from the received signals, a definable frequencyband is advantageously traversed per temperature measurement, i.e., permeasurement run. Based on the frequency-dependent signal intensities ofthe received response signals, the resonance frequency can then bedetermined, and the cooked product temperature can in turn be derivedfrom the latter. The determined cooked product temperature cansubsequently be sent by the evaluator to a display of the basic unit ofthe food processor and displayed there. Alternatively and/oradditionally, the determined cooked product temperature can also be usedfor regulating a cooking process inside of the cooking container asdescribed in the invention. Regulating the current temperature inside ofthe cooking container here enables a recipe preparation that has beenoptimized with respect to the currently measured temperature from thestandpoint that the duration of heat exposure and/or intensity of heatexposure are retroactively influenced as a function of the temperature,for example. On the one hand, a heating device situated in the vessel,for example a heating plate situated on the vessel floor, can here beused to increase or decrease the heating capacity in the vessel, so asto achieve an increase or decrease in temperature inside of the cookingcontainer as well. Alternatively and/or additionally, however, use canalso be made of a heating device situated in the cooking containeritself, or of one of several partial heating devices, in particular soas to bring about an increase or decrease in temperature in definedcooking zones of the cooking container.

Even though a new temperature measurement can basically be performedwith the use of wired temperature sensors, the invention preferablyproposes that the transceiver device communicate wirelessly with SAWsensors.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be explained in more detail below based on exemplaryembodiments. Shown on:

FIG. 1 is a food processor with a vessel and a cooking containersituated thereon,

FIG. 2 is a sectional view of a partial area of the vessel with acooking container situated thereon according to a first embodiment,

FIG. 2a is a sectional view of the partial area of the vessel withtemperature sensors in the vessel;

FIG. 2b is a sectional view of a partial area of the vessel withtemperature sensors in another cooking container in the vessel;

FIG. 3 is a sectional view of a partial area of the vessel with acooking container situated thereon according to a second embodiment.

DESCRIPTION OF THE EMBODIMENTS

FIG. 1 shows a food processor 1, which here is designed as acooker-mixer, for example. The food processor 1 exhibits a basic unit 14along with a vessel 2 incorporated therein (here: mixing vessel) with anagitator 18 and a vessel cover 15. The vessel cover 15 has a centralcover opening 16, through which steam generated in the vessel 2 can flowinto a cooking container 3 situated on the vessel 2. The vessel 2 of thefood processor 1 has allocated to it a heating device 9 (see FIG. 2) forheating the vessel 2. An agitator is also potentially situated in thevessel 2. The food processor 1 further exhibits a transceiver device 12as well as an evaluator 13. Both are allocated to the basic unit 14 ofthe food processor 1.

The cooking container 3 is here designed as a cooking attachment thatcan be placed on the vessel 2. The cooking container 3 is sealed with acover, which potentially exhibits openings that allow steam to escape.

The cross section depicted on FIG. 2 shows an upper partial area of thevessel 2 with the vessel cover 15 as well as the cooking container 3.The vessel cover 15 seals the vessel 2 at least partially, wherein thecentral cover opening 16 is formed on the vessel cover 15, through whichsteam can flow out of the vessel 2 into the cooking container 3.

The cooking container 3 exhibits a wall 4 that borders a cooking zone 6,and incorporates several temperature sensors 5. Formed in a floor areaof the cooking container 3 is a heating device 9, which is annularlysituated around the cover opening 16 of the vessel cover 15. Forexample, the heating device 9 can be an electrical resistance heaterwith individual resistance elements. The temperature sensors 5 are heredesigned as SAW sensors, which can communicate wirelessly by radio withthe transceiver device 12 of the basic unit 4 of the food processor 1.To supply power to the heating device 9 of the cooking container 3, thelatter has a network connection for supplying voltage to the heatingdevice 9. Even though the cooking container 3 has its own mains plug inthe exemplary embodiments shown, the heating device 9 can alternativelyalso be supplied with voltage via the basic unit 14 of the foodprocessor 1. If the cooking container 3 has a separate voltage supply asdepicted, the cooking container 3 can also be used as a standalonedevice, so that the latter can also be used independently of the foodprocessor 1 and/or the heatable vessel 2. In alternative embodimentsshown in FIGS. 2a and 2b , the temperature sensors 5 can also beincorporated into the vessel 2 and/or into a cooking container 3disposed in the vessel 2.

FIG. 3 shows a second embodiment, in which the cooking container 3exhibits a cooking container insert 17 in the form of a shelf, whichexhibits several temperature sensors 5 and several (specifically twohere) partial heating devices 10, 11. The partial heating devices 10, 11are each concentrically situated around floor openings 8 formed in thecooking container insert 17. The cooking container 3 and cookingcontainer insert 17 are supplied with voltage via the basic unit 14 ofthe food processor 1. To this end, the basic unit 14, vessel 2, vesselcover 15 and wall 4 of the cooking container 3 or cooking containerinsert 17 exhibit electrical lines. Corresponding electrical contactsfor ensuring the supply of electricity are situated at the interfacesbetween the food processor 1 and vessel 2, vessel 2 and vessel cover 15,vessel cover 15 and cooking container 3 or cooking container 3 andcooking container insert 14. The temperature sensors 5 and partialheating devices 10, 11 are each embedded into the wall 4 of the cookingcontainer 3 or cooking container insert 17. The interior of the cookingcontainer insert 17 or the interior of the cooking container 3 eachcomprise a cooking zone 6, 7 for cooked product contained therein.

The invention functions in such a way that the user of the foodprocessor 1 fills the vessel 2 with a liquid, for example water, andseals it with the vessel cover 15. The cooking container 3 is situatedon the vessel cover 15. Cooked product to be cooked is introduced intothe cooking container 3. The cooking container 3 is sealed with a cover.If necessary, one or more cooking container inserts 17 (see FIG. 3) canadditionally be introduced into the cooking container 3, thereby formingseveral levels inside of the cooking container 3.

The liquid contained in the vessel 2 is heated by means of the heatingdevice 9 allocated to the vessel 2. As soon as the boiling point of theliquid has been reached, steam rises from the vessel 2 and escapesthrough the cover openings 16 into the cooking container 3 or cookingcontainer insert 17. The wall 4 of the cooking container 3 or cookingcontainer insert 17 is here heated, along with the cooked productssituated in the cooking container 3 or cooking container insert 17. Inaddition, the heating device 9 of the cooking container 3 (FIG. 2) orthe partial heating devices 10, 11 of the cooking container 3 andcooking container insert 17 (FIG. 3) can already be used for thesupplemental heating of the cooked product at this point in timealready.

The partial heating devices 10, 11 according to FIG. 3 can here becontrolled independently of each other, so that different cooking zonescan be formed inside of the cooking container 3 or cooking containerinsert 17. For example, the partial heating device 10 of the cookingcontainer insert 17, which is located farther away from the flooropenings 8 than the partial heating device 11, can be operated at ahigher temperature, so that cooked product situated in the cookingcontainer insert 17 is uniformly heated, regardless of the radialdistance of the cooked product relative to the floor openings 8 throughwhich the hot steam of the vessel 2 flows. In like manner, the partialheating devices 10, 11 of the cooking container insert 17 can beoperated at a higher temperature than the partial heating device 10 ofthe cooking container 3, through which the hot steam initially flowsbefore finally penetrating into the cooking container insert 17. As aresult, a uniform temperature can be achieved both in the cookingcontainer insert 17 and the cooking container 3 itself, so that similarcooked products are exposed to the same temperature. Alternatively,however, a temperature different than the one in the cooking zone 6 ofthe cooking container 3 can be set in the cooking zone 7 of the cookingcontainer insert 17, for example. In addition, additional levels, e.g.,cooking zones 6, 7, with varying temperatures can also be formed in thecooking container insert 17 or remaining area of the cooking container3. A different type of cooked product can then be situated in each ofthese cooking zones 6, 7, for example fish inside a first cooking zone 6and vegetables in a second cooking zone 7. Due to the plurality ofcooking zones 6, 7, the cooked products contained in the cookingcontainer 3 or cooking container insert 17 can be fully cooked by thesame point in time, even given characteristics that deviate from eachother.

The respective current temperature inside of the different cooking zones6, 7 is measured by means of the respective temperature sensors 5situated there. In the examples shown here with SAW sensors as thetemperature sensors 5, the transceiver device 12 of the basic unit 14transmits an excitation signal to the temperature sensors 5. Thetemperature sensors 5 have a component structure that exhibits atemperature-dependent resonance frequency, i.e., amplifies a specificfrequency as a function of temperature. The transceiver device 12 heretransmits a plurality of excitation signals with deviating frequenciesof a defined frequency band in chronological sequence. The frequenciesare tailored to the component structure of the temperature sensors 5, aswell as to the expected temperatures. Each temperature sensor 5 hereexhibits a frequency range that deviates from the other temperaturesensors 5, so that the transmitted measurement data can be allocated toa specific temperature sensor 5.

Each excitation signal of the transceiver device 12 triggers a specificresponse signal in the respective temperature sensor 5, so that thetemperature sensor 5 sends a temperature-dependent response signal backto the transceiver device 12. Since not all frequencies are uniformlyamplified within the component structure of the respective temperaturesensor 5 as a function of the current temperature of the cooked productin the area of a temperature sensor 5, the signal intensity of theresponse signal can be used to determine the temperature which thecooked product situated there currently exhibits. The response signalsreceived by the transceiver device 12 are relayed to the evaluator 13,and there compared with temperature-dependent reference frequencies. Ifan excitation signal of the transceiver device 12 corresponds with aresonance frequency of the respective temperature sensor 5 at a currenttemperature, the signal intensity of this response signal is higher thanthe signal intensities of the response signals relative to frequenciesdeviating from the latter. The response signals received by thetransceiver device 12 from the respective temperature sensor 5 are henceanalyzed with respect to the response signal with the highest signalintensity, so that the temperature currently present at the respectivetemperature sensor can be reliably determined. The higher the number ofexcitation signals within the defined frequency band, the moreinformative the measuring result. The currently determined temperaturescan subsequently be compared with the temperatures desired for preparingthe cooked product. If a deviation is found, for example too low atemperature in the area of the cooking zone 7 of the cooking containerinsert 17, the partial heating devices 10 and/or 11 are set to a higherheating capacity, so as to reach the desired temperature value. Inaddition, the temperature sensors 5 here keep continuously measuring thetemperature. This results in a control circuit in which the temperatureof the partial heating devices 10, 11 or even the partial heating device9 of the vessel 2 or cooking container 3 is regulated as a function ofthe determined temperature difference between the current temperaturemeasured by the temperature sensor and the desired temperature. As aconsequence, the heating capacity and/or heating duration can be usedfor successful recipe preparation. This in particular byraising/lowering the intensity of heat exposure and/or duration of heatexposure.

The heating device 9 or partial heating devices 10, 11 are turned on andoff automatically by a controller of the food processor 1, for exampleby the evaluator 13. As a consequence, the heating device 9 or partialheating devices 10, 11 can be automatically operated as a function of acurrent preparation stage in a recipe and the measurement data of thetemperature sensors 5. Even though not depicted on the figures, theinvention can of course also function in such a way that only theheating device 9 of the vessel 2 is operated, and only its heatingcapacity or heating duration is regulated as a function of themeasurement result of the temperature sensors 5 of the cooking container3 or cooking container insert 17. As a result, either the heating device9 of the vessel 2 can be used as a central heating device, oralternatively a plurality of partial heating devices 10, 11 can beprovided, which are advantageously situated directly in the cookingzones 6, 7.

Even though the invention was illustrated primarily as relates totemperature sensors situated on the cooking container, i.e., the cookingattachment, it is of course also possible to situate the temperaturesensors in the sense of the invention on the vessel of the foodprocessor and/or other spatially variable elements of the foodprocessor, for example a spatula for manipulating the cooked product. Ofcourse, temperature sensors can also be simultaneously situated on thevessel, cooking container and/or spatula or on other accessories. Eachof the proposed spatially variable elements can here exhibit either justa single temperature sensor or also several temperature sensors at thesame time.

REFERENCE LIST

-   -   1 Food processor    -   2 Vessel    -   3 Cooking container    -   4 Wall    -   5 Temperature sensor    -   6 Cooking zone    -   7 Cooking zone    -   8 Floor opening    -   9 Heating device    -   10 Partial heating device    -   11 Partial heating device    -   12 Transceiver device    -   13 Evaluator    -   14 Basic unit    -   15 Vessel cover    -   16 Cover opening    -   17 Cooking container insert    -   18 Agitator

The invention claimed is:
 1. An electrically operated food processor (1)for preparing a cooked product, comprising: a basic unit (14), a vessel(2) that can be inserted into the basic unit (14), a cooking, container(3) that is configured to be placed in or on the vessel, a heatingdevice (9) connected to the vessel (2), an agitator connected to thevessel, a plurality of temperature sensors (5), a transceiver device(12) for communicating with the temperature sensors (5), and anevaluator (13) for evaluating measurement data received from thetemperature sensors (5), wherein the temperature sensors are surfaceacoustic wave sensors (SAW sensors), wherein at least one of the vesseland cooking container has cooking zones that exhibit differenttemperatures, and wherein at least two of said temperature sensors aresituated in the cooking zones that exhibit different temperatures.